In order for our site to display correctly you will need a newer version of your web browser.

Please note that this is not intended to be an exhaustive list of browsers that support web standards, nor a test of browser compliance, nor a side-by-side comparison of various manufacturers’ browsers.

Related Topics

Tumor suppressor protein is a key regulator of immune response and balance

Memphis, Tennessee, July 18, 2011

St. Jude Children’s Research Hospital scientists provide insight into immune system biology and identify the mechanism that keeps white blood cell activity at a minimum until the specific immune response is needed

St. Jude Children’s Research Hospital scientists have identified a key immune system regulator, a protein that serves as a gatekeeper in the white blood cells that produce the “troops” to battle specific infections.

Researchers demonstrated the protein, Tsc1, is pivotal for maintaining a balanced immune system and combating infections. Loss of the Tsc1 protein was associated with a reduction in the number of certain immune cells and a weaker immune response. The work appears in the July 17 online edition of the scientific journal Nature Immunology.

Scientists found that Tsc1 works by inhibiting the pathway that launches production of the specialized white blood cells known as effector T cells. Those cells are the backbone of the adaptive immune response, designed to respond, identify and destroy specific bacteria, viruses and other threats.

Working in mice with specially engineered immune systems, scientists showed Tsc1 also keeps cellular activity at a minimum in the white blood cells known as naïve T cells. That process is known as quiescence.

Quiescence has long been recognized as crucial to proper immune function. But until now scientists were unclear how quiescence was established and maintained in naïve T cells. “This study is the first to show that Tsc1 is a primary regulator of T cell quiescence,” said Hongbo Chi, Ph.D., assistant member St. Jude Department of Immunology, and the study’s senior author. The first author is Kai Yang, Ph.D., a postdoctoral fellow in Chi’s laboratory.

“These findings not only advance understanding of the cell biology of the immune system but also have great potential for clinical applications in the future,” Chi said. He speculated that the same process might also be important in regulating immune cells known as memory T cells that help the immune system recognize infectious agents encountered before and mount a rapid immune response.

Tsc1 is best known as a tumor suppressor, helping to prevent cancer development by inhibiting activity of the mTOR protein and the pathway that bears its name. The mTOR pathway plays a key role in cancer, metabolic disease and aging.

Now Chi and his colleagues demonstrated that in the immune system Tsc1 has a unique job. Through inhibition of the mTOR pathway, Tsc1 forces naïve T cells to maintain minimal metabolic and cellular activity. Normally that would only change when naïve T cells are activated and begin producing the more specialized effector T cells to combat a specific new threat.

In this study, scientists showed that loss of the Tsc1 protein predisposed affected T cells to premature activation, resulting in programmed cell death via the cell’s suicide pathway. Consequently, the process depleted the supply of T cells as well as another group of specialized immune cells known as invariant natural killer T cells. The loss also dampened the ability of mice to combat bacterial infections. “We think maintaining T cell quiescence is central to preventing premature cell death and ensuring a productive immune response,” Chi said.

Although more work is needed to understand mTOR regulation of T cell quiescence, this study offers a glimpse into the process. Tsc1 is part of a larger complex known to regulate mTOR activity. The mTOR protein is also a component in two larger complexes, known as mTORC1 and mTORC2. Chi and his colleagues demonstrated that naïve T cell quiescence requires Tsc1 to keep mTORC1 activity at a low level. If Tsc1 is lost or shut down prematurely, mTORC1 activity increases, leading to premature activation of the immune cells, which results in various abnormalities and cell death.

Other authors are Geoffrey Neale, Douglas Green, both of St. Jude; and Weifeng He, formerly of St. Jude.

The research was supported in part by the National Institutes of Health, the Arthritis Foundation, the Lupus Research Institute and ALSAC.

St. Jude Children’s Research Hospital St. Jude Children’s Research Hospital is internationally recognized for its pioneering research and treatment of children with cancer and other catastrophic diseases. Ranked one of the best pediatric cancer hospitals in the country, St. Jude is the first and only National Cancer Institute-designated Comprehensive Cancer Center devoted solely to children. St. Jude has treated children from all 50 states and from around the world, serving as a trusted resource for physicians and researchers. St. Jude has developed research protocols that helped push overall survival rates for childhood cancer from less than 20 percent when the hospital opened to almost 80 percent today. St. Jude is the national coordinating center for the Pediatric Brain Tumor Consortium and the Childhood Cancer Survivor Study. In addition to pediatric cancer research, St. Jude is also a leader in sickle cell disease research and is a globally prominent research center for influenza.

Founded in 1962 by the late entertainer Danny Thomas, St. Jude freely shares its discoveries with scientific and medical communities around the world, publishing more research articles than any other pediatric cancer research center in the United States. St. Jude treats more than 5,700 patients each year and is the only pediatric cancer research center where families never pay for treatment not covered by insurance. St. Jude is financially supported by thousands of individual donors, organizations and corporations without which the hospital’s work would not be possible.